WO2003062053A1 - Joint for connecting a longitudinal side to an upper side of components and flexible strip for use in such a joint - Google Patents

Abstract

Joint for connecting a longitudinal side of a first component (4) to the upper side of a second component (T3), comprising at least two co-operating strips (41a, 41b; 42a, 42b; 51a, 51b; 61a, 61b; 71a, 71b), each fixed at the first end (E1) thereof to different, opposing sides of the first component (T4), the second ends (E2) of which are each fixed to a tensioning element (45, 46; 52a, 52b; 62a, 62b; 72a, 72b) arranged on the second component (T3) such as to intersect the longitudinal mid-axis (A) of the first component (T4) in opposing directions in the region between the components (T3, T4). Said joint further comprises a pressure element (15) bearing on at least one tensioning element for mounting the first component (T3), whereby the strips, lateral to the pressure and viewed in the axial direction (R1), run obliquely to each other.

Description

 Joint for connecting a long side to an upper side of components and flexible band for use for such a joint

The invention relates to a joint for a component arrangement in which a longitudinal side of a first component faces an upper side of a second component, and to a flexible band for use for such a joint.

To improve the aerodynamic properties of wings, concepts for a wing with a variable profile that can be adjusted via control mechanisms are known from the general prior art. However, these concepts use a relatively large number of moving parts and joints, which mean a high outlay in terms of their manufacture and assembly.

For example, US 4,349,169 discloses an aerofoil with a profile that can be changed by means of an actuator. Drive rods of the actuator are connected to the structure of the wing by means of joints, the axial direction of the joints running in the spanwise direction. This makes it possible to change the profile if several actuators with corresponding actuating rods are arranged one behind the other, as seen in the span direction. However, the profile shape change disclosed there takes place over the entire span direction in this object.

Furthermore, EP 860 355 discloses an aerodynamic component with a variable curvature, which is formed from articulated ribs with an outer belt and a plurality of stiffening struts which act on it and are constant in length. The stiffening struts are actuated to deform the component by means of actuators in such a way that the stiffening struts move in the longitudinal direction of the ribs or the direction of flow.

From DE 28 07 648 C2 a folding wall with wall parts connected by a fabric joint is known. The fabric joint is a band attached to its Longitudinal edges are provided with an edge rib. The edge rib is held in a groove running along the end face of the wall part with a corresponding recess that is wider than the groove.

The object of the invention is to provide a joint which is simple in construction and easy to install and which is an alternative to the joints used today.

This object is achieved with the features of the independent claims. Further embodiments are specified in the subclaims.

According to the invention, a joint is provided for connecting a long side of a first component to an upper side of a second component with at least two interacting bands, which are fastened with their first ends E1 to different, opposite sides of the first component and with their second ends E2 are each attached to a clamping element arranged on the second component in such a way that they intersect the longitudinal central axis of the first component in opposite directions in the area between the components, with a pressure element located on at least one clamping element for mounting the first Component, wherein the bands run to the side of the pressure element and seen in the axis direction to each other crosswise. The tapes can be formed from at least two layers of a fiber composite material or another plastic or a textile material. The bands can extend in their longitudinal direction at an angle β to the axis direction of the structural joint, the angle β being unequal to 90 degrees for absorbing thrust forces to be transmitted through the joint. The bands can be fastened between a tensioning element and the second component.

The invention is described below with reference to the attached figures. Show it: 1 is a schematic perspective view of an embodiment of the joint according to the invention, in which the kinetics and kinematics are entered in an arrow representation,

2 shows the embodiment of the joint according to FIG. 1 in section with an arrow representation of the kinetics and kinematics,

3 shows a further embodiment as a variant A of the joint according to the invention,

4 shows a further embodiment as a variant B of the joint according to the invention,

5 shows a further embodiment as a variant C of the joint according to the invention,

Fig. Βa is a schematic representation of the shear force curve when using flexible band for a joint that does not fix according to the invention, but e.g. is constructed as a fabric,

6b shows a schematic representation of the shear force curve when using flexible tape for a joint which is arranged in a matrix, e.g. in a resin layer.

Flexible joint bands or bands or flexible straps or belt elements are used for the joints according to the invention for the articulated connection of two mutually movable components are not fixed with each other. In the following, the free joint area FG is understood to be the area between the two connected components. The free joint area FG is also the area of the ligaments on which the ligaments of the joint do not rest against the components in any of the predetermined positions. In contrast, each flexible band provided according to the invention has a fixed region B, to which the band is attached to the respective component or is firmly connected to it. Areas can also be included on these tapes, which are in contact with the component or components, but which are not fixed or attached to them.

The joint according to the invention is a structural joint, since its components can be formed from materials that have similar properties to the components connected to it, so that the behavior of the joint, even when subjected to forces or under tension, changes its behavior of the components.

In particular, a fiber composite (FV) material or another plastic or a textile material or fabric is provided as the material for the tapes used according to the invention. The bands provided are formed from at least two layers of the material described above. The layers are not fixed to one another in the area F, that is to say in the area between the components T1, T2 to be connected to the joint, in order to keep the thrust forces FS of the resulting thrust force curve V-FS as low as possible (FIG. 6a). Otherwise there would be an unfavorable course of thrust forces FS (FIG. 6b).

1 to 5 is a structural joint according to the invention or a structural joint arrangement according to the invention for connecting at least two components T3 and T4, which are shown in a neutral position. In this position, the components form a T arrangement. In principle, the components can form an angular arrangement in their neutral position. 1 to 5 serves to connect a long side of a first component T4 to a top of a second component T3, in which at least one pressure element arranged between the long side and the top is used for the formation a free joint area FG and two flexible bands interacting with it can be used.

According to the invention, an articulated connection is provided for connecting a long side of a first component T4 to an upper side of a second component T3 with at least two interacting bands which are fastened with their first ends E1 to different, opposite sides of the first component T4 and the are fastened with their second ends E2 to a respective clamping element arranged on the second component T3 in such a way that their courses with respect to a longitudinal central axis A of the first component T4 run opposite to one another or in the region between the components the longitudinal central axis Cut A of the first component in opposite directions or that these cut the longitudinal central axis A of the first component in opposite directions in the area between the components, with a pressure element located on at least one clamping element for mounting the first component T3, the Bands on the side of the Pressure element and seen in the axis direction R1 to each other crosswise. In particular, the components in interaction with the at least one pressure element form a free articulated area FG or two free articulated areas laterally next to this, in or in which the bands each run from one to the other component. The tapes can be arranged on one side of the printing element or one on both sides of the same. Two pressure elements are preferably provided in order to achieve stable mounting of the relevant component T4.

The bands can extend in their longitudinal direction at an angle β to the axis direction R2 of the structural joint, the angle β being in particular not equal to 90 degrees to absorb thrust forces to be transmitted by the joint. The joint shown in FIG. 1 in a schematic diagram or the joint arrangement 40 comprises two arrangements, each with two flexible bands 41a, 41b or 42a, 42b and a total of three pressure elements 15, one pressure element between the two arrangements of bands and one pressing element to the side of the two arrangements of bands. Two clamping elements 45, 46 in the form of clamping plates are arranged on the component T3, a clamping element 45 or 46 being located on each side of the component T4.

The course of the bands in the exemplary embodiment shown is as follows: Each flexible band 41a, 41b or 42a, 42b runs from a first side of component T4 - e.g. Page 47 - in the area between the component T3 and the clamping element, which is next to the component T4, on the opposite side to the first side of the component T4 - in the example next to page 48. From there it runs flexible band on the side of the tensioning element 45 facing away from the component T4 to the free side of the tensioning element facing away from the component T3, where the band is preferably fastened. At least one additional flexible band is arranged for each flexible band, which, contrary to the described course of component T4, is placed around the tensioning element. The kinematics in this arrangement as a function of the angles α and β is shown in FIG. 8. The angle α is the angle that the bands 45, 46 assume in the free joint area FG with respect to the surface of the component T3.

Various alternatives for the course of the strips and the positions of the tensioning elements relative to the component T4 are shown in FIGS. 3 to 5, only two strips being shown in each case. Basically, two or more than two ligaments can be used for the joint according to the invention. The description of their course is essentially described using one of the two illustrated tapes. The course of the at least one further band arises accordingly in order to bring about an opposite flow of force occurring in the bands, as shown in FIG. 2. The component T4 shown in each case is oriented in its neutral position with its transverse direction R3 at an angle to the surface of the component T3. 3 to 5, an angle of 90 degrees is shown as an example for this neutral position. A first band is guided around a first tensioning element and a second band is guided around a second tensioning element from component T4, the bands being in the free joint area FG in the longitudinal direction R1 of the components or Seen axis direction of the joint are one behind the other and their longitudinal directions cross. According to the invention, at least two interacting bands are used, which are fastened with their first ends E1 to different, opposite sides of the first component T4 and which are each fastened to a clamping element arranged on a second component T3, the position of the clamping -Elements allow the straps to be fastened on opposite sides with respect to a central axis A of the first component T4. According to the invention, the courses of at least two bands with respect to a longitudinal central axis of the first component T4 are opposite to each other.

The tensioning elements are fastened to the component T3 together with the bands, preferably by means of connecting elements. A pressure element 15 is arranged on a tensioning element or on both tensioning elements (FIG. 5) in such a way that the component T4 is mounted in its intended articulated positions on a corresponding bearing surface 15a of the pressure element 15. For this purpose, one or both clamping elements can each have a tongue Z or a support area AB for receiving a pressure element 15. A support area AB can be arranged on a tongue Z. The tongue Z of a clamping element projects into the area between the second component T3 and the side surface of the first component T4 facing it. The tongues lying one behind the other in the axial direction R2 of overlapping clamping elements in this direction overlap. Since the strips rest on the surfaces of the tongues Z facing them, the strips are guided in such a way that bands lying next to each other cross each other in the axis direction R2 (see FIGS. 3 to 5).

In the embodiment according to FIG. 3, the two flexible belts 51a, 51b fastened to the component T4 are used. The two cross-sections of both clamping elements protrude so far into the extension of component T4 in its longitudinal direction R3 that the ligaments emanating from component T4 are located next to one another in the free joint area and run transversely to one another. Seen in the longitudinal direction of the components T3, T4, there is a fictitious intersection point P of the strips. This point P is the pivot point of the joint.

The respective band can be guided starting from component T4 after passing through the free joint area FG between component T3 and either the first tensioning element 52a (FIG. 3) or the second tensioning element 52b (FIG. 4), and then on the free surface of the clamping element 52a or 52b in question. Starting from one side of the component T4, each band runs through the free joint area FG to the component T3 and crosses the longitudinal central axis A of the component T4 when passing through the free joint region. From there, the band runs around the cross section of a tensioning element, first between the two tensioning elements, then at least partially into the area between one of the tensioning elements and the component T3 and preferably around the free outside of the same tensioning element - Element around to a predetermined part of the free outside of the same clamping element.

Each band is passed through an area or a passage D which is kept free by two tensioning elements. The position of this kept free area is either in the area of the cross section of the extension of the component T4 in the direction of the component T3 (FIGS. 3 and 4) or to the side of this area (FIG. 5). However, this area is located in such a way that the band in question from one side of the component T4 in the free joint area FG at the pivot point P can be guided over the central axis of component T4. From there, this band runs either in the direction in which it crosses the central axis A, to a tensioning element (FIGS. 4 and 5), where it is fastened between the latter and the component T3. Alternatively, the band is fastened on that side with respect to the central axis A between a tensioning element and the component T3, on which it is fastened to the component T4.

The attachment of the band in question at its first end E1 to component T4 takes place in various ways according to the prior art. The tape can be glued or fastened to the component T4 by means of connecting elements.

In particular, a fiber composite (FV) material or another plastic or a textile material or fabric is provided as the material for the tapes used according to the invention. The bands provided are formed from at least two layers of the material described above. The layers are not fixed to one another in the area F, that is to say in the area between the components T1, T2 to be connected to the joint, in order to keep the shear forces FS of the resulting shear force profile V-FS as low as possible (FIG. 6a). Otherwise there would be an unfavorable course of thrust forces FS (FIG. 6b).

The straps can be fixed or fastened to the component T3 according to the prior art, e.g. by gluing, by fastening elements or by fusing the materials of the respective band with the respective component.

The straps are preferably attached at their second end E2 to the respective tensioning element by means of connecting elements. 9 to 11 show that on a first clamping element by means of at least one connecting element 54a, which runs transversely to the component T3 and the first clamping element 52a and extends through the component T3, through the first clamping element 52a and the section of the band located between them. The band in question is preferably guided around the edge side 56a of the tensioning element 52a facing away from the component T4, on the outside 57a lying opposite the component T3. The first connecting element 54a thereby extends on the one hand through an area of the flexible band located between the first tensioning element 52a and the component T3, and through an area of the band located on the outside 57a of the tensioning element 52a. For this purpose, a corresponding hole for receiving the first connecting element 54a is arranged in the first clamping element 52a.

A cavity H is preferably provided in the first clamping element 52a, through which the first connecting element 54a extends. The cavity H is advantageously open to the component T3. Through the cavity H, the first tensioning element 52a is extended or stretched in the transverse direction R2 of the tensioning element 52a, that is to say in the longitudinal direction of the band, when the first connecting element 54a is tightened, in order to tension the band in question.

A second connecting element 54a is advantageously provided near the free joint area FG or near the component T4. This second connection element 54a extends - like the first connection element 54a - through the component T3, through an area of the flexible band located between the first tensioning element 52a and the component T3, through the first tensioning element 52a and also through an area of the band located on the outside 57a of the tensioning element 52a. A corresponding bore is arranged in the first clamping element 52a to accommodate the first connecting element 54a.

The second clamping element 52b is by means of a further connecting element

54c attached to component T3. Its position is provided relative to the first tensioning element 52a so that the flexible band can be passed between them.

The second clamping element 52b can additionally be used to attach another flexible band 51 of the same joint can be provided. The course with respect to the central axis A is then opposite and preferably symmetrical to the course of the band fastened to the first tensioning element.

According to the invention, at least two flexible bands running opposite to a central axis A of the component T4 are arranged, the fastening of the at least two bands being fastened to at least two tensioning elements 52a, 52b extending transversely to the longitudinal direction of the components T3, T4. To attach the at least two tapes, more than two, e.g. four clamping elements can be used. These are then offset in a manner transverse to the longitudinal direction R1 of the components T3, T4 in such a way that the flexible bands in the free articulated area FG can be placed next to one another, running crosswise, around the contact surfaces of the respective clamping elements.

FIG. 4 shows an alternative course of a flexible band 61a according to the invention. The flexible band 61a is fastened to a first tensioning element 62a, which is arranged on the opposite side with respect to the central axis A of the component T4. For this purpose, the second clamping element 62b protrudes correspondingly far into the extension of the cross section of the component T4 in the direction of the component T3 in order to form the intersection of the corresponding extensions of the bands 61a, 61b in the longitudinal direction R1 of the component, which is preferably the pivot point P is the components.

In the embodiment of FIG. 11 with the bands 71a, 71b, the tensioning elements 72a, 72b are arranged in such a way that the passage D formed by them is located in the region of the extension of the cross section of the component T4 to the component T3.

According to the invention, a support element can be arranged on the side of the pressure element facing the first component T4. This overlay element can have a sliding layer which is located on that surface of the support element which faces the first component T4. Furthermore, the side of the support element facing the first component T4 can have a larger radius of curvature than the surface of the first component T4 facing this, in order to reduce pressure stresses that occur.

Claims

claims

1. Joint for connecting a long side of a first component (T4) to an upper side of a second component (T3) with at least two interacting bands (41a, 41b; 42a, 42b; 51a; 51b; 61a, 61b; 71a, 71b) are fastened with their first ends (E1) to different, opposite sides of the first component (T4) and with their second ends (E2) to a respective clamping element (45, 46) arranged on the second component (T3) ; 52a, 52b, 62a, 62b; 72a, 72b) are fastened in such a way that they cut in the area between the components (T3, T4) the longitudinal center axis (A) of the first component (T4) in opposite directions, with one At least one tension element 15 located pressure element for mounting the first component (T3), the bands extending crosswise to one another as seen to the side of the pressure element and in the axis direction (R1).

2. Joint for connecting a long side of a first component (T4) to an upper side of a second component (T3) according to claim 1, characterized in that the bands (41a, 41b; 42a, 42b; 51a; 51b; 61a, 61b; 71a, 71b) are formed from at least two layers of a fiber composite material or another plastic or a textile material.

3. Joint for connecting a long side of a first component (T4) to an upper side of a second component (T3) according to claim 1 or 2, characterized in that the strips (41a, 41b; 42a, 42b; 51a; 51 b; 61a, 61 b; 71a, 71 b) in their longitudinal direction at an angle β to the axis direction (R2) of the structural joint, the angle β being unequal to absorb thrust forces to be transmitted through the joint Is 90 degrees.

4. Joint for connecting a long side of a first component (T4) to an upper side of a second component (T3) according to one of the preceding methods. Sayings, characterized in that the bands (41a, 41b; 42a, 42b; 51a; 51b; 61a, 61b; 71a, 71b) between a tensioning element (45, 46; 52a, 52b, 62a, 62b; 72a, 72b ) and the second component are attached.

5. Joint for connecting a long side of a first component (T4) with an upper side of a second component (T3) according to claim 4, characterized in that the bands (41a, 41b; 42a, 42b; 51a; 51b; 61a, 61b; 71a, 71b) in each case through the area between a clamping element (45, 46; 52a, 52b, 62a, 62b; 72a, 72b) and the second component through to the surface of the clamping element lying opposite to this area and the straps are fastened by means of a connecting element (54a, 54c) that projects through the second component, the tensioning element and a region of the respective strap located between the tensioning element and the second component and an area located on the second component.

6. Joint for connecting a long side of a first component (T4) to an upper side of a second component (T3) according to one of the preceding claims, characterized in that it has a cavity (H) which is connected by means of a tensioning element (45, 46; 52a, 52b, 62a, 62b; 72a, 72b) is deformable in order to change the extension of the tensioning element in the longitudinal direction of the respective strap to tension the strap.

7. Joint for connecting a long side of a first component (T4) to an upper side of a second component (T3) according to one of the preceding claims, characterized in that the bands (41a, 41b; 42a, 42b; 51a; 51b; 61a , 61b; 71a, 71b) are arranged one behind the other as seen in the axis direction.

8. Joint for connecting a long side of a first component (T4) to an upper side of a second component (T3) according to one of the preceding methods. Sayings, characterized in that a support element is arranged on the side of the pressure element (15) facing the first component (T4).

9. joint for connecting a long side of a first component (T4) to an upper side of a second component (T3) according to de claim 8, characterized in that the support element has a sliding layer which is located on that surface of the support element, which faces the first component (T4).

10. Joint for connecting a long side of a first component (T4) to an upper side of a second component (T3) according to one of claims 8 or 9, characterized in that the side of the support element facing the first component (T4) has a larger radius of curvature has than the surface of the first component (T4) facing this, in order to reduce compressive stresses that occur.

11. Flexible band for use in a joint connection according to one of the preceding claims, characterized in that the band (41a, 41b; 42a, 42b; 51a; 51b; 61a, 61b; 71a, 71b) from at least two layers from a company - Serverbund material or another plastic or a textile material is formed.